Microrobotics for MEMs and Nanotechnologies

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Presentation transcript:

Microrobotics for MEMs and Nanotechnologies Microrobotic Components: 1.) Sensors 2.) Actuators introduction, examples (SPM) 3.) Bearing & Guidance System “Guidages”, “Führungen” 4) Control! Integral part of 1-3) Hannes Bleuler EPFL, LSRO Laboratoire de Systèmes Robotiques

In Microrobotics, these components are very much integrated!

Sensors: Classification criteria What is measured? (distance, force, pressure, T, t, frequ., light, field, chemical composition …)

Sensors: Classification criteria what Physical Principle (Optical, acoustical, electrostatic, magnetic, hall, inductive, eddy currents, dilatation, piezoelectric, piezoresistive, magnetnetoresistive…)

Sensors: Classification criteria what Physical principle Metrological principles: absolute, relative, incremental, averaging, local, intensity, time of flight, phase, Indirect meast.: nulling.

Sensors: Classification criteria what Physical principle Metrology Technology (Analog, discrete, integrated (MEMS), thick-film, Screen Printing, electronics (CMOS,CCD,SMD…)

standard Printed Circuit board Example: Technology choice (PCB) leads to new sensor: Transverse Flux Sensor excitation coil pickup coil standard Printed Circuit board Analog RF Electromagnetic Distance, conductivity PCB technology Philippe Bühler, ISMB 9, Aug. 2004

Transverse Flux Sensor Excitation frequ. 20 kHz to 3 MHz depending on electr. & magnetic properties of target material Potential for high precision since there is averaging over large target area. Unaffected by low frequ. & static fields.

Simple structure: Easy to adapt to harsh environements (hot, UHV, corrosive, liquid) Little effect of temperature: Has been made for T up to 500 °C UHV compatibility! In these cases not PCB, but screen printing on Alumine substrate, Ag–Pd conductors

for Local Measurements Other example

Just like an actuator, a sensor is basically a transducer from one form of energy to another Disturbances Input power e.g. mechanical Output power e.g. electrical Losses

Piezoelectric transducers: Piezo as an actuator: charge –> strain –> stress Piezo as a sensor: stress –> strain –> charge

Piezoelectric materials quartz (weak) salt (very weak) polycrystaline ferroelectric ceramics: BaTiO3, Lead Zirconate Titanate (PZT)

Basic mechanism: Stress –> strain –> charge Also charge –> strain (actuator) complex geometry (polarisation direction, strain tensor, shear…) small displacements, high forces, high voltages (µm to tens of µm for cm size PZT, 100s of Volt) nonlinearity, hysteresis Ceramics –> brittle –> prestress